A short wavelength reduction projection optical system used for transferring integrated circuit patterns from a reticle to a wafer in a semiconductor manufacturing system. The optical system has object side and image side virtually telecentric, high resolution over a wide exposure area, and adequately compensates for optical aberrations without increasing the length of the optical system. The optical system has a first group of lenses with weak refractive power, a second group of lenses with a positive refractive power, a third group of lenses with a negative refractive power, a fourth group of lenses with a positive refractive power, and an aperture stop located between the third and fourth groups of lenses.
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1. An optical system comprising, in order from an object side to an image side:
a first group of lenses; a second group of lenses with a positive refractive power; a third group of lenses with a negative refractive power; a fourth group of lenses with a positive refractive power; an aperture stop disposed between said third group of lenses and said fourth group of lenses; wherein said optical system satisfies the following conditions:
|En|>L |Ex|>|L/β| wherein L is a distance between an object and an image of said optical system, En is a distance measured from a first optical surface on the object side of said optical system to an entrance pupil of said optical system, Ex is a distance measured from a last optical surface on an image side of said optical system to an exit pupil of said optical system, and β is an overall magnification of said optical system. 2. The system of
-2.3<β1/β<-1.6 |f1|>L wherein β1 is a magnification of said first group of lenses and f1 is a focal length of said first group of lenses. 3. The system of
2<β4/β<3 δ34/L>0.05 wherein β4 is a magnification of said fourth group of lenses and δ34 is an axial distance from a last optical surface of said third group of lenses to a first optical surface of said fourth group of lenses. 4. The system of
0.09<f4/L<0.16 wherein f4 is a focal length of said fourth group of lenses. 5. The system of
wherein f2 is a focal length of said second group of lenses. 6. The system of
-0.12<f3/L<-0.06 wherein f3 is a focal length of said third group of lenses. 7. The system of
8. The system of
q32<-0.2 wherein q32 is a shape factor defined by the following equation: q32 =(C1+C2)/(C1-C2) wherein C1 is a curvature of an object side surface of said negative refractive power lens and C2 is a curvature of an image side surface of said negative refractive power lens. 9. The system of
a front group of lenses with a positive refractive power; and a rear group of lenses with a negative refractive power.
10. The system of
said front group of lenses of said first group of lenses includes at least two positive refractive power lenses; and said rear group of lenses of said first group of lenses includes at least two negative refractive power lenses.
11. The system of
12. The system of
13. The system of
|f4b/L|<0.13 wherein f4b is a focal length of said at least one negative refractive power lens in said fourth group of lenses. 14. The system of
15. The system of
16. The system of
17. The system of
h4a/(h4max>0.9) wherein h4a is a maximum height of a paraxial marginal ray on each optical surface of said at least a second negative refractive power lens and h4max is a maximum height of said paraxial marginal ray in said fourth group of lenses. 18. The system of
f4a/L<-1 3<q4a<5 wherein f4a is a focal length of said at least a second negative refractive power lens and q4a is a shape factor of said at least a second negative refractive power lens, wherein said shape factor q4a is defined by the following equation: q4a =(C3+C4)/(C3-C4) wherein C3 is a curvature of an object side surface of said at least a second negative refractive power lens and C4 is a curvature of an image side surface of said at least a second negative refractive power lens. 19. The system of
20. The system of
21. The system of
22. The system of
23. The system of
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1. Field of the Invention
This invention relates generally to optical systems and, more particularly, to projection optical systems used in semiconductor manufacture and, even more particularly, to short wavelength reduction projection optical systems used for transferring integrated circuit patterns from a reticle to a wafer.
2. Discussion of Related Art
In semiconductor device manufacturing, projection optical systems are used to transfer integrated circuit (IC) patterns such as large scale integrated (LSI) circuit patterns from a reticle, also known as a mask, onto a wafer or semiconductor substrate upon which the semiconductor device is being formed. Because of the difference in the relative sizes of the reticle and the resulting semiconductor device, also known as a die or a semiconductor chip, the projection optical system must be a reduction projection optical system. Modern integrated circuits are becoming more integrated; that is, more and more functions are being integrated into circuits to be placed onto a single die. At the same time, however, there is a major effort not to allow the die to grow in size in order to maintain or improve the performance and speed of the semiconductor device being manufactured. Therefore, to maintain the same or reduced die size, the reduction projection optical system must have a wider exposure area and a higher resolution.
One method to increase the resolution of the optical system is to illuminate the reticle with shorter wavelength illumination. In principle, the shorter the wavelength, the higher the resolution. In the search for shorter wavelength illumination sources, there have been identified two excimer lasers that can be used: the KrF excimer laser with a 248 nanometer wavelength and the ArF with a 193 nanometer wavelength. These excimer lasers are to replace the mercury-arc lamp as an illumination source for semiconductor manufacturing. The mercury-arc lamp supplies the g-line that has a wavelength of 436 nanometers and the i-line that has a wavelength of 365 nanometers from the ultraviolet spectrum of the mercury-arc lamp. These two ultraviolet lines are presently the principle illumination sources used in semiconductor wafer manufacturing.
The major problem with utilizing the shorter wavelengths provided by the excimer lasers is the limited availability of optical materials suitable for use in the wavelength range of the excimer lasers. The principal reason the optical materials are unsuitable is that the transmission factor of most optical materials is too limited to be used at these short wavelengths. Currently, the following two optical materials are considered feasible for use in short wavelength systems: fused silica (SiO2) and fluorite (CaF2). These optical materials, however, have low refractive indices compared to other optical materials. The use of optical materials with low refractive indices makes compensation of optical aberrations more difficult when designing an optical system with the required high resolution.
Many of these projection optical systems are nearly image-side telecentric which means the exit pupil is located virtually at infinity. The advantage of using an optical system with image-side telecentricity or near image-side telecentricity is that variations in projection magnification are negligible or can be easily compensated. These variations are caused by errors in the optical axis direction such as focus errors during exposure and variations in the flatness of the image surface, which in this case, is the wafer. Up to now, variations in the flatness of the mask could be ignored; however, because circuit patterns are becoming smaller, variations in the mask can no longer be ignored.
What is needed is a reduction projection optical system in which both the object side and image side are telecentric, which has high resolution over a wide exposure area, and which adequately compensates for optical aberrations while maintaining the present overall length of the optical system. The overall length of the projection optical system cannot be increased because the size is constrained by the plant (a stage in a semiconductor manufacturing system) and the overall system size.
The present invention is directed to a projection optical system with, in order from the object side, a first group of lenses, a second group of lenses with a positive refractive power, a third group of lenses with a negative refractive power, and a fourth group of lenses with a positive refractive power. An aperture stop is disposed between the third group of lenses and the fourth group of lenses. The overall optical system satisfies the following conditions:
|En|>L and |Ex|>|L/β|,
where En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system; L is the distance between an object and an image of the optical system; Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system; and β is the overall magnification of the optical system.
The overall optical system also satisfies the following conditions:
-2.3β1/β<-1.6 and |f1|>L,
where β1 and f1 are the magnification and the focal length of the first group of lenses, respectively.
The overall optical system also satisfies the following conditions:
2<β4/β<3 and δ34/L>0.05,
where β4 is the magnification of the fourth group of lenses and δ34 is the axial distance from the last surface of the third group of lenses to the first surface of the fourth group of lenses.
The fourth group of lenses in the optical system satisfies the following condition:
0.09<f4/L<0.16,
where f4 is the focal length of the fourth group of lenses.
The second group of lenses in the optical system satisfies the following condition:
0.1<f2/L<0.2,
where f2 is the focal length of the second group of lenses.
The third group of lenses in the optical system satisfies the following condition:
-0.12<f3/L<-0.06,
where f3 is the focal length of the third group of lenses.
The third group of lenses in the optical system includes a pair of concave optical surfaces facing each other, and one embodiment of the invention has a negative refractive power lens disposed between the pair of concave optical surfaces. The negative refractive power lens satisfies the following condition:
q32<-0.2,
where the shape factor q32 is defined by the following equation:
q32=(C1+C2)/(C1-C2),
where C1 is the curvature of the object side optical surface and C2 is the curvature of the image side optical surface of the negative refractive power lens.
The first group of lenses in the optical system has a front group of lenses with a positive refractive power and a rear group of lenses with a negative refractive power. In the first embodiment of the present invention, the front group of lenses has two positive refractive power lenses and the rear group of lenses has two negative refractive power lenses. In the second embodiment of the present invention, the rear group has three negative refractive power lenses and the front group has two positive refractive power lenses. In the third embodiment of the present invention, the fourth group of lenses has an additional negative refractive power lens. In the fourth embodiment of the present invention, the front group of lenses of the first group of lenses has three positive refractive power lenses and the rear group has three negative refractive power lenses. In the fifth embodiment of the present invention, the front group of lenses of the first group of lenses has three positive refractive power lenses and the rear group of lenses of the first group of lenses has four negative refractive power lenses. In the sixth embodiment of the present invention, the second group of lenses has five positive refractive power lenses. In the seventh embodiment of the present invention, the front group of lenses of the first group of lenses has four positive refractive power lenses and the rear group of lenses of the first group of lenses has four negative refractive power lenses and the fourth group of lenses has an additional negative refractive power lens.
The accompanying drawings, incorporated in and forming a part of the specification, illustrate the present invention and, together with the description, serve to explain the principles of the invention. In the drawings:
FIG. 1A shows a lens arrangement according to a first embodiment of the present invention.
FIGS. 1B-1E show measured optical aberrations of the lens arrangement shown in FIG. 1A.
FIG. 2A shows a lens arrangement according to a second embodiment of the present invention.
FIGS. 2B-2E show measured optical aberrations of the lens arrangement shown in FIG. 2A.
FIG. 3A shows a lens arrangement according to a third embodiment of the present invention.
FIGS. 3B-3E show measured optical aberrations of the lens arrangement shown in FIG. 3A.
FIG. 4A shows a lens arrangement according to a fourth embodiment of the present invention.
FIGS. 4B-4E show measured optical aberrations of the lens arrangement shown in FIG. 4A.
FIG. 5A shows a lens arrangement according to a fifth embodiment of the present invention.
FIGS. 5B-5E show measured optical aberrations of the lens arrangement shown in FIG. 5A.
FIG. 6A shows a lens arrangement according to a sixth embodiment of the present invention.
FIGS. 6B-6E show measured optical aberrations of the lens arrangement shown in FIG. 6A.
FIG. 7A shows a lens arrangement according to a seventh embodiment of the present invention.
FIGS. 7B-7E show measured optical aberrations of the lens arrangement shown in FIG. 7A.
FIG. 8 shows a schematic setup of a scanning exposure apparatus in which the projection optical system according to the present invention can be applied.
FIG. 9 shows the sectional structure of a photosensitive substrate.
FIG. 10 shows the schematic setup of an exposure apparatus of the one-shot exposure method in which the projection optical system according to the present invention can be applied.
Referring now to the Figures, the embodiments of the present invention will now be described. FIG. 1A shows an optical system lens arrangement according to a first embodiment of the present invention. According to standard practice in the optical art, drawings of optical system lens arrangements, such as those shown in the Figures, have the object space, defined as all the space from the first element or surface of a system towards the object and beyond, on the left in the drawing; therefore, the image space is on the right side of the drawing. Shown in FIG. 1A is an object 12 in object space and an image 14 in image space.
The lens arrangement 10 in FIG. 1A, viewed from the object side, in order of succession, includes a first group of lenses G1, a second group of lenses G2 with an overall positive refractive power, a third group of lenses G3 with an overall negative refractive power, a fourth group of lenses G4 with an overall positive refractive power, and an aperture stop AS, indicated at 16, disposed between lens group G3 and lens group G4.
In order to make the lens system 10 in FIG. 1A telecentric in both image space and object space, the following conditions are satisfied:
|En|<L; and
|Ex|>|L/β|,
wherein L is the distance between object 12 and image 14 of the optical system 10, En is the distance measured from the first optical surface 18 on the object side of optical system 10 to an entrance pupil (not shown), Ex is the distance measured from the last optical surface 20 on the image side of optical system 10 to an exit pupil (not shown), and β is the overall magnification of the optical system 10.
The condition|En|>L establishes an entrance pupil position where the entrance pupil is defined as the image of the aperture stop AS 16 as seen from object space. If the condition|En|>L is not satisfied, an angle of the chief ray emerging from the object plane cannot be made small and, thus, image distortion on the image plane caused by a deflection of the object plane is not negligible and is difficult to compensate. A chief ray is any ray in the object space that passes through the center of the entrance pupil.
The condition|Ex|>|L/β| establishes an exit pupil position where the image of the aperture stop AS 16 as seen from image space, is known as the exit pupil of the system. If the condition|Ex|>|L/β| is not satisfied, an image distortion caused by deflection in the wafer is not negligible and is difficult to compensate.
In order to have both image space and object space telecentric in an optical system, it is necessary to have a lens group with an overall positive refractive power arranged on the object side of the optical system and a lens group with an overall positive refractive power arranged on the image side with an aperture stop between them. The positioning of lens groups on the object side and the image side of an aperture stop allows the placement of the entrance pupil and the exit pupil at virtual infinity by the proper selection of lenses in both the positive refractive power lens groups and the remaining lenses in the optical system.
In order to obtain high resolution and a wide exposure area at the same time, image field curvature has to be substantially eliminated. When a lens is corrected for spherical aberration and coma, it is termed an aplanat. When it is also corrected for astigmatism, it is termed an anastigmat. Even when these three major aberrations are corrected, the system may still have an aberration called image field curvature. In an anastigmat, the tangential and sagittal surfaces collapse to a single image surface called the Petzval surface which, unfortunately, does not resemble the shape of the object surface which is usually flat, especially in the semiconductor industry in which the object field is the reticle. In a positive refractive power lens system which has image field curvature, a real image will be found on a surface curving toward the object. The radius of curvature of the image surface is called the Petzval radius, and the aberration is called Petzval curvature or field curvature. An expression of the Petzval theorem, which is well known to a person of ordinary skill in the optical art and can be found in various optics textbooks, for example, Elements of Modern Optical Design, by Donald C. O'Shea, Wiley Interscience, John Wiley & Sons, New York, 1985, pp. 198-202, contains a summation term known as the Petzval sum. The image field curvature and the Petzval sum are closely related in that the image field curvature aberration can be decreased by decreasing the Petzval sum. The Petzval sum can be decreased by strengthening the negative refractive power at a point where the height of a marginal ray from an axial object point is minimal. A marginal ray is defined as an axial ray traced near the outer edge of a lens system. An axial ray is defined as a ray that starts at an angle from the optic axis in the object plane. A marginal ray, therefore, is a ray that starts on the optic axis in the object plane at an angle that allows the ray to just get through the optical system. Any ray that starts at a larger angle will be blocked by some element, such as the aperture stop, in the optical system. The lens arrangement shown in FIG. 1A is constructed so as to locate a group of lenses G3 with a negative refractive power near the aperture stop AS 16. The lens group G3 is disposed between the positive refractive power group of lenses G2 and the positive refractive power group of lenses G4. However, simply arranging a group of lenses with an overall negative refractive power near an aperture stop in an optical system with a large projection magnification ratio with groups of positive refractive power lenses on either side of the negative refractive power group of lenses would result in a longer distance between an object and an image, and such a reduction projection lens system would be impractical for use in the semiconductor manufacturing industry. Therefore, another group of lenses is necessary to maintain the required compactness of the projection optical system to be used in a semiconductor manufacturing system. This added group of lenses is located on the most object side of the optical system, and in FIG. 1A this additional group of lenses is G1. The group of lenses G1 acts as a reduction afocal relay system for a chief ray which emerges from an object almost parallel to the optical axis. An afocal system is one in which the object and image are both located at infinity. The near afocal lens group G1 enables a large reduction in entrance and exit chief ray heights while maintaining a near parallel condition with the optical axis. This is because the additional lens group G1 is designed with substantially no refractive power and, therefore, does not contribute significantly to the refractive power of the optical system as a whole. The lens group G1 allows the height of the chief ray to be changed significantly which allows the system to have a large projection magnification ratio while maintaining a desired distance between the object and the image, that is, between the reticle and the wafer.
In order to obtain the necessary weak refractive power in the first group of lenses G1, the following conditions are satisfied preferably:
-2.3<β1/β<-1.6 and
|f1|>L,
wherein β1 is a magnification of the first group of lenses G1 and f1 is the focal length of the first group of lenses.
For discussion purposes, the first group of lenses G1 is divided into two lens groups. From the object side, in order of succession, there is a front group of lenses G1f with a positive refractive power and a rear group of lenses G1r with a negative refractive power.
The condition -2.3<g1/g<-1.6 provides for the ratio of the magnification β1 of the first group of lenses G1 to the magnification β of the overall optical system. At above the upper limit of the condition -2.3<β1/β<-1.6, the magnification ratio of the first group of lenses G1 becomes small, and a large difference in height of the chief ray cannot be achieved which results in making the distance L between the object and image too large. On the other hand, below the limit of the condition -2.3<β1/β<-1.6, although the difference in height of a chief ray can be achieved, the refractive power of the front group of lenses G1f and the rear group of lenses G1r becomes too strong to sufficiently compensate for distortion and coma aberration. Because of this, the magnification of the first lens group G1 is set to satisfy the condition -2.3<β1/β<-1.6. In addition, because the optical system of the present invention is virtually telecentric on both the image and object sides, the condition |f1|>L, although providing directly for the focal length f1, provides indirectly for an angle of a chief ray emerging from the first group of lenses G1. Beyond the range of the condition |f1|>L, where the refractive power of the first group of lenses G1 becomes too strong on the negative side, the variation of the angle of the chief ray in the first group of lenses G1 becomes too large. This makes it difficult to adequately compensate for distortion. On the other hand, at a focal length beyond the range of the condition |f1|>L, where the refractive power of the first group of lenses G1 becomes too strong on the positive side, and contrary to the situation above, it will be convenient to compensate for distortion; however, the difference between an angle of refraction of a chief ray emerging from the first group of lenses G1 and an angle of refraction of the marginal ray, becomes too large which makes it difficult to compensate for coma.
In the first embodiment shown in FIG. 1A, G1f includes two lenses with positive refractive power and G1r includes two lenses with negative refractive power. One lens in each group could be used; however, using only one positive refractive power lens in G1f could result in the curvature of each optical surface of the single lens to be too strong to compensate for distortion adequately while controlling an angle of a chief ray in order to have an optical system whose object side is as close to telecentric as possible. If only one lens is used in the rear group G1r of the first group G1 of lenses, the curvature at each optical surface could become too strong to adequately compensate for coma. This is because the angle of incidence of the marginal ray from an off-axis object, in particular, becomes too large.
Here, it is preferred that the second group of lenses G2 has a positive refractive power and satisfies the following condition:
0.1<f2/L<0.2,
wherein f2 is the focal length of the second group of lenses G2. At below the lower limit of 0.1<f2/L<0.2, the positive refractive power of the second group of lenses G2 becomes too strong which would necessitate increasing the negative refractive power of the rear group of lenses G1r of the first group of lenses G1 and the negative refractive power of the third group of lenses G3 sufficiently to balance the increase in the positive power necessary to go below the lower limit of condition 0.1<f2/L<0.2. The requirement to maintain the positive and negative refractive power balance is to maintain the compensation for the Petzval sum as discussed above. At above the upper limit of the condition 0.1<f2/L<0.2, the positive refractive power of the second group of lenses G2 becomes too weak and because the negative refractive powers of the rear group of lenses G1r of the first group of lenses G1 and G3 cannot be made strong enough to compensate for the decrease in the positive refractive power of G2, the Petzval sum becomes large. This makes it difficult to adequately compensate for the image field curvature.
In the first embodiment of the lens system shown in FIG. 1A, the second group of lenses G2 includes three positive refractive power lenses with the first optical surface S21 on the first lens in the second group of lenses G2 being concave facing the object side. It may be possible to have less than three positive refractive power lenses in the second group of lenses G2; however, if there are less than three positive refractive power lenses, the curvature of each optical surface must be too strong to maintain the positive refractive power of the second group of lenses G2 to satisfy the condition 0.1<f2/L<0.2. In addition, it becomes difficult to compensate for the coma and spherical aberration that would be caused by the strong curvature of these optical surfaces. For this reason, it is desirable that the necessary positive refractive power of the second group of lenses G2 be divided amongst at least three positive refractive power lenses. The reason the first optical surface in the second lens group G2 is concave and faces the object side is to decrease the angle of incidence of the ray bundle from the first group of lenses G1 onto the second group of lenses G2. The small angle of incidence assists in keeping coma and spherical aberration small.
In the first embodiment shown in FIG. 1A, the third group of lenses G3 is a lens group with an overall negative refractive power disposed on the object side of aperture stop AS 16. The third group of lenses G3 is arranged more preferably to satisfy the condition:
-0.12<f3/L<-0.06,
wherein f3 is the focal length of the third group of lenses G3. Above the upper limit of the condition -0.12<f3/L<-0.06 the negative refractive power of the third group of lenses G3 becomes too strong and, although it is advantageous for compensating for the Petzval sum, it makes compensating for coma and spherical aberration more difficult. On the other hand, below the lower limit of the condition -0.12<f3/L<0.06, the negative refractive power of the third group of lenses G3 becomes too weak, and the compensation of the Petzval sum becomes insufficient. This means that compensating for the image field curvature is made more difficult. The embodiment shown in FIG. 1A, shows a pair of concave optical surfaces S32 and S31 with a negative refractive power lens 22 between the two concave optical surfaces S32 and S35.
The placement of third lens group G3 with an overall negative refractive power between second lens group G2 and fourth lens Group G4, each having positive refractive power, causes a marginal ray from the axial object point to have a minimum value, and the arrangement of the concave optical surfaces facing each other in such a manner as to maintain the minimum value results in allowing an angle of incidence with respect to a ray bundle to be small, while strengthening the curvature of the optical surface with negative refractive power. By strengthening this surface, the Petzval sum is made small and thus, coma caused by these lenses is made as small as possible. By having at least one negative refractive power lens 22 located between the pair of concave optical surfaces S32 and S35, the negative refractive power borne by each individual lens surface which is required to compensate for the Petzval sum is reduced. This, in turn, minimizes the individual surface contribution to coma aberration.
In addition to minimizing the above discussed aberrations, if the shape factor q of the negative refractive power lens 22 satisfies the condition q<-0.2, astigmatism can be minimized provided that the shape factor is defined by the following equation:
q=(C1+C2)/(C1-C2),
wherein the curvature of the first optical surface from the object side of each lens is C1, and the curvature of the second optical surface is C2.
The ratio between the composite focal length of the groups of lenses on the object side of the aperture stop AS 16 and the composite focal length of the group of lenses on the image side of the aperture stop AS 16 is made as close to the desired projection magnification as possible in order to reduce the aberration caused by the structure of the optical system. Therefore, the third group of lenses G3 is placed on the object side of aperture stop AS 16 such that the higher magnification ratio can be accommodated. The negative refractive power lens disposed between the pair of concave optical surfaces S32 and S35 weakens the component working against the symmetric property around aperture stop AS 16 by making the curvature of the concave optical surface S41, located on the object side of the fourth lens group G4, somewhat weak which contributes to reducing the difference between the meridional image point and the sagittal image point which contributes to the compensation of astigmatism.
If possible, it is desirable to have the shape factor q of the negative refractive power lens 22 satisfy the condition q>-1. Below this lower limit the symmetric property of the lenses on either side of the aperture stop AS 16 is improved; however, compensation of the Petzval sum and coma aberration becomes more difficult.
In the first embodiment shown in FIG. 1A, the fourth group of lenses G4 is a group of lenses with an overall positive refractive power arranged on the image side of aperture stop AS 16. To adequately compensate for the Petzval sum, the projection optical system is arranged more preferably to satisfy the following conditions:
2<β4/β<3 and
δ34/L>0.05,
wherein β4 is the magnification of the fourth group of lenses G4 and δ34 is the axial space between the last optical surface S36 of the third group of lenses G3 and the first optical surface S41 of the fourth group of lenses. The negative refractive power of the third group of lenses G3 can be increased and the Petzval sum compensated by having a large difference in height of the marginal ray at the third group of lenses G3 with an overall negative refractive power and at the fourth group of lenses G4 with a positive refractive power. The condition δ34/L>0.05 sets axial distance δ34 and, together with condition 2<β4/β<3, provides that the incident angle of the slope of the paraxial marginal ray is within an appropriate range in order to obtain a sufficient difference in height of the paraxial marginal ray.
The condition 2<β4/β<3 directly provides for the ratio of the magnification β4 of the fourth group of lenses G4 to the magnification β of the optical system 10. However, because the magnification β and the numerical aperture on the image side are already determined, the condition 2<β4/β<3 provides for the angle of the paraxial marginal ray of the ray bundle incident on the fourth group of lenses G4.
Below the lower limit of condition 2<β4/β<3, an angle of the paraxial marginal ray of the ray bundle incident on the fourth group of lenses G4 is too small to obtain a sufficient difference in height of the paraxial marginal ray. Therefore, the height of the marginal ray at the third group of lenses G3 is not small enough to strengthen the negative refractive power, and the Petzval sum cannot be compensated enough to adequately compensate the field curvature.
Above the upper limit of condition 2<β4/β<3, the angle of the paraxial marginal ray of the ray bundle incident on the fourth group of lenses G4 is too large; and, although it is convenient for the compensation of the Petzval sum, the coma aberration generated there cannot be adequately compensated because the negative refractive power of the third group of lenses G3 is too strong.
Below the lower limit of condition δ34/L>0.05, the Petzval sum is not being adequately compensated due to the lack of the difference in height of the paraxial marginal ray. It is furthermore desirable to set the upper limit of condition δ34/L>0.05 at 0.1 to more adequately balance the limit of the distance L between the object and the image and the compensation for optical aberrations.
In order for the fourth group of lenses G4 to receive the ray bundle diverged by the third group of lenses G3, the angle of the ray bundle within the fourth group of lenses G4 should be changed gradually to minimize the angle of incidence at each lens surface in the fourth group of lenses G4. Therefore, the fourth group of lenses G4 is preferably arranged to satisfy the condition
0.09<f4/L<0.16,
wherein f4 is the focal length of the fourth group of lenses G4.
At a ratio below the lower limit of condition 0.09<f4/L<0.16, the focal length f4 of the fourth group of lenses G4 is too short and the length of the fourth group of lenses G4 is short which would be advantageous in reducing the overall size of the optical system 10; however, because the positive refractive power of the fourth group of lenses becomes too strong, it would be difficult to compensate for various optical aberrations, in particular, coma and spherical aberration.
At a ratio above the upper limit of condition 0.09<f4/L<0.16, the focal length f4 of the fourth group of lenses G4 is too long and the distance from the aperture stop AS 16 to the image plane becomes longer and would cause the size of the optical system to become larger, which is undesirable.
The first embodiment shown in FIG. 1A includes six positive refractive power lenses in the fourth group of lenses G4 and a negative refractive power lens L4b with a concave optical surface 24 facing the image side. The six positive refractive power lenses share the required strong positive refractive power allowing the angle of the ray bundle within the fourth group of lenses G4 to be changed gradually to minimize the angle of incidence at each optical surface in the fourth group of lenses G4. Another reason to have at least six positive refractive power lenses in the fourth group of lenses G4 is that because the fourth group of lenses G4 receives an expanded ray bundle from the third group of lenses G3, the contribution of the fourth group of lenses G4 to spherical aberration can be significant and cannot be adequately compensated unless there are a significant number of positive refractive power lenses in the fourth group of lenses G4. By having the concave surface of the negative refractive power lens L4b facing the image side, the angle of incidence with respect to the ray bundle with a large numerical aperture converged at an image point can be made small which makes the various optical aberrations small. To achieve this, the lens L4b is arranged more preferably to satisfy the following condition:
|f4b/L|<0.13,
wherein f4b is the focal length of the negative refractive power lens L4b.
At beyond the range of the condition |f4b/L|<0.13, the negative refractive power becomes too weak and it is difficult to adequately compensate for coma and spherical aberration. Example 1 is a listing of numerical values for Embodiment 1 shown in FIG. 1A. The optical surfaces are numbered from the object side to the image side, each lens of course having two surfaces. It is noted that in the following examples, a single glass material, fused silica (SiO2) with an index of refraction of 1.5084 at the wavelength λ of 248 mm, is used as the optical material for all lenses of the projection optical system.
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Object plane to first optical surface = 100.000 mm |
Last optical surface to image plane = 15.203 mm |
En = 2890.681 mm |
Ex = 4431.639 mm |
f1 = -12368.327 mm |
f2 = 147.910 mm |
f3 = -100.116 mm |
f4 = 141.728 mm |
β1 = 0.5401 |
β4 = -0.6267 |
q32 = -0.3415 |
f4b = -98.205 mm |
δ34 = 83.771 mm |
β = -0.25 |
L = 980.000 mm |
Radius of axial lens |
Surface # |
curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 Infinity 21.972 SiO2 |
2 -219.5343 0.500 |
3 418.1439 22.903 SiO2 |
4 -372.1487 55.092 |
5 228.2689 13.200 SiO2 |
6 92.9574 20.901 |
7 -242.8683 13.200 SiO2 |
8 152.7388 35.238 |
9 -83.6596 54.246 SiO2 |
10 -137.0918 0.500 |
11 -527.7039 22.786 SiO2 |
12 -211.5084 0.500 |
13 305.1996 39.999 SiO2 |
14 -309.0586 0.500 |
15 326.3851 27.483 SiO2 |
16 1029.3143 0.500 |
17 101.2218 20.693 SiO2 |
18 90.6354 39.144 |
19 -267.5363 13.200 SiO2 |
20 131.3186 35.422 |
21 -113.1086 22.457 SiO2 |
22 -743.8803 65.268 |
AS Infinity 18.503 |
23 -377.6071 23.981 SiO2 |
24 -215.1420 0.500 |
25 2352.6425 27.858 SiO2 |
26 -316.8095 0.500 |
27 500.0254 36.719 SiO2 |
28 -566.9346 0.500 |
29 201.8472 42.566 SiO2 |
30 1337.8302 0.500 |
31 196.1627 32.164 SiO2 |
32 598.1194 0.500 |
33 139.3671 50.074 SiO2 |
34 213.1926 11.440 |
35 9000.0000 50.040 SiO2 |
36 49.5517 18.833 |
37 48.0703 20.415 SiO2 |
38 1571.0501 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses (along the optical axis). |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, δ34 is the axial distance from the last optical surface of the third group of lenses to the first optical surface of the fourth group of lenses, β is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
The embodiments of the present invention shown in FIGS. 1A-7E are shown with measured aberrations for each of the seven embodiments. The measurements were made with a projection optical system of the present invention using a KrF excimer laser with a wavelength of 248 nanometers, a system magnification of 0.25, an image side numerical aperture of 0.6, and a diameter of the image side exposure area is 26.4 millimeters. FIGS. 1B to 1E show measured optical aberrations of the lens arrangement as shown in FIG. 1A.
Referring now to FIGS. 2A-7E, embodiments 2 through 7 will now be explained. In each of the Figures, like numerical designations will be the same for like components as shown in FIG. 1A.
FIG. 2A shows a second embodiment of the present invention. Embodiment 2 differs from embodiment 1 in that embodiment 2 has three negative refractive power lenses in the rear group G1r of the first group of lenses G1, whereas embodiment 1 has two negative refractive power lenses. The added negative refractive power lens provides improved aberration compensation. FIGS. 2B to 2E show measured optical aberrations of the lens arrangement shown in FIG. 2A. Example 2 is a listing of numerical values for Embodiment 2 shown in FIG. 2A.
______________________________________ |
Object plane to first optical surface = 100.005 mm |
Last optical surface to image plane = 15.146 mm |
En = 3167.690 mm |
Ex = 4499.500 mm |
f1 =-7786.016 mm |
f2 = -143.587 mm |
f3 = -96.931 mm |
f4 = 140.130 mm |
β1 = 0.532 |
β4 = -0.6267 |
q32 = -0.3580 |
f4b = -100.376 mm |
δ34 = 83.250 mm |
β = -0.25 |
L = 980.004 mm |
Radius of axial lens |
Surface # |
Curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 2885.7578 22.338 SiO2 |
2 -225.8625 0.500 |
3 292.3214 23.235 SiO2 |
4 -570.9909 32.507 |
5 171.9983 13.200 SiO2 |
6 102.7355 15.520 |
7 247.7947 13.200 SiO2 |
8 112.8554 17.339 |
9 -285.1155 19.524 SiO2 |
10 184.7278 30.188 |
11 -82.8626 55.022 SiO2 |
12 -133.2816 0.500 |
13 -558.7588 23.285 SiO2 |
14 -211.8646 0.500 |
15 287.9933 38.933 SiO2 |
16 -360.6154 0.500 |
17 291.9108 29.232 SiO2 |
18 -1047.2563 0.500 |
19 101.2961 20.417 SiO2 |
20 90.4508 38.782 |
21 -272.8878 13.200 SiO2 |
22 129.0010 34.605 |
23 -115.4078 22.894 SiO2 |
24 -1276.1960 65.482 |
AS Infinity 17.768 |
25 -390.0579 23.653 SiO2 |
26 -217.6774 0.500 |
27 5786.7268 30.606 SiO2 |
28 -324.3366 0.500 |
29 528.2130 34.304 SiO2 |
30 -596.4222 0.500 |
31 195.3567 42.014 SiO2 |
32 1173.4808 0.500 |
33 195.0500 30.775 SiO2 |
34 544.8555 0.500 |
35 136.8421 47.721 SiO2 |
36 209.9488 11.371 |
37 4581.9271 51.322 SiO2 |
38 50.2785 19.402 |
39 48.9832 22.014 SiO2 |
40 2090.6182 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses. |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, δ34 is the axial distance from the last optical surface of the third group of lenses to the first optical surface of the fourth group of lenses, β is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
FIG. 3A shows a third embodiment of the present invention. The third embodiment includes four positive refractive power lenses in the second group of lenses G2. The addition of a positive refractive power lens to embodiment 3 allows the curvature of each positive refractive power lens surface to be weakened which reduces the aberration generated at each surface. A negative refractive power lens 26 is added to the fourth group of lenses G4 at the position where the ray bundle is widest which generates an opposite aberration providing improved refractive power balance. Example 3 is a listing of numerical values for Embodiment 3 shown in FIG. 3A.
______________________________________ |
Object plane to first optical surface = 100.022 mm |
Last optical surface to image plane = 15.401 mm |
En = 3430.501 mm |
Ex = 6214.553 mm |
f1 = -1629.975 mm |
f2 = 132.791 mm |
f2 = 132.791 mm |
f3 = -83.063 mm |
f4 = 122.333 mm |
β1 = 0.478 |
β4 = -0.6267 |
q32 = -0.2500 |
f4b = -92.242 mm |
δ34 = 51.719 mm |
h4a = 85.103 mm |
h4max = 91.718 mm |
f4a = -1102.065 mm |
q4a = 3.670 β = -0.25 |
L = 980.001 mm |
Radius of axial lens |
Surface # |
Curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 1035.4918 23.355 SiO2 |
2 -243.8838 0.882 |
3 202.5420 26.395 SiO2 |
4 -583.4769 18.415 |
5 189.2260 13.827 SiO2 |
6 109.2412 14.229 |
7 260.5493 13.200 SiO2 |
8 112.2878 21.138 |
9 -129.3924 13.200 SiO2 |
10 162.7234 70.326 |
11 -93.7255 35.314 SiO2 |
12 -130.6305 0.500 |
13 -434.5127 24.568 SiO2 |
14 -189.6052 0.500 |
15 3472.0293 29.708 SiO2 |
16 -332.9038 0.500 |
17 279.0422 44.078 SiO2 |
18 -424.5560 0.500 |
19 233.3057 24.361 SiO2 |
20 693.7685 0.500 |
21 147.2276 29.622 SiO2 |
22 102.9836 35.341 |
23 -223.2687 13.200 SiO2 |
24 133.9612 31.903 |
25 -126.4786 14.396 SiO2 |
26 -9000.0000 36.951 |
AS Infinity 14.768 |
27 -490.9308 24.929 SiO2 |
28 -190.8527 0.500 |
29 698.5103 28.798 SiO2 |
30 -406.1288 0.500 |
31 261.7071 38.226 SiO2 |
32 -823.4878 18.270 |
33 -233.8363 13.200 SiO2 |
34 -408.9672 0.500 |
35 353.5677 38.745 SiO2 |
36 -415.4598 0.500 |
37 138.1435 37.331 SiO2 |
38 794.2109 0.500 |
39 121.6915 23.093 SiO2 |
40 169.5366 13.835 |
41 -980.2205 41.588 SiO2 |
42 49.9566 12.423 |
43 49.4098 19.963 SiO2 |
44 763.1561 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses. |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, δ34 is the axial distance from the last optical surface of the third group of lenses to the first optical surface of the fourth group of lenses, h4a is the maximum height of a paraxial marginal ray on each optical surface of the second negative refractive power lens in the fourth group of lenses, h4max is the maximum height of a paraxial marginal ray in the fourth group of lenses, f4a is the focal length of the second negative refractive power lens of the fourth group of lenses, q4a is the shape factor of the second negative refractive power lens, β is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
The fourth group of lenses G4 with the addition of negative refractive power lens 26 satisfies the following condition:
h4a/h4max>0.9,
wherein h4a is the maximum height of the paraxial marginal ray at each surface of the negative refractive power lens L4a 26 and h4max is the maximum height of the paraxial marginal ray in the fourth group of lenses G4. By arranging the negative refractive lens L4a 26 within the range of condition h4a/h4max>0.9, the height of the paraxial marginal ray is utilized to control the negative refractive power from becoming too strong which makes it possible to efficiently adjust coma and spherical aberration. In addition, it is desirable for the following conditions to be satisfied:
f4a/L<-1 and
3<q4a<5,
wherein f4a is the focal length of lens L4a 26 and q4a is the shape factor of lens L4a 26. Beyond the range of condition f4a/L<-1, the refractive power is too strong because the height of paraxial marginal ray is large and the contribution of the negative refractive power to the refractive power of the entire system becomes too strong, which in turn requires the positive refractive power to be stronger for balance. The stronger curvatures of the surfaces in the individual lenses would make it more difficult to compensate for high order aberration. Beyond the upper limit of the condition 3<q4a<5, the degree of meniscus of L4a becomes stronger causing the angle of incidence and the angle of refraction of the marginal ray at the negative refractive power lens L4a to become too large to compensate for higher order aberrations. Below the lower limit of the condition 3<q4a<5, aberration cannot be compensated adequately with less negative refractive power and, as a result, the condition f4a/L<-1 becomes more difficult to satisfy. FIGS. 3B to 3E show measured optical aberrations of the lens arrangement as shown in FIG. 3A.
FIG. 4A shows a fourth embodiment of the present invention. The fourth embodiment includes three positive refractive power lenses in the front lens group G1f in the first group of lenses G1. The three positive refractive power lenses allow better compensation of aberrations by dividing up the positive refractive power between three positive refractive power lenses. FIGS. 4B to 4E show measured optical aberrations of the lens arrangement as shown in FIG. 4A. Example 4 is a listing of numerical values for Embodiment 4 shown in FIG. 4A.
______________________________________ |
Object plane to first optical surface = 114.250 mm |
Last optical surface to image plane = 15.455 mm |
En = 4093.415 mm |
Ex = -5751.189 mm |
f1 = -1593.699 mm |
f2 = 126.222 mm |
f3 = -79.002 mm |
f4 = 119.507 mm |
β1 = 0.4826 |
β4 = -0.6267 |
q32 = -0.2500 |
f4b = -91.467 mm |
δ34 = 52.620 mm |
h4a = 84.294 mm |
h4max = 90.239 mm |
f4a = -1229.760 mm |
q4a = 3.882 |
β = -0.25 |
L = 980.001 mm |
Radius of axial lens |
Surface # |
Curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 734.3406 21.818 SiO2 |
2 -340.2643 0.500 |
3 285.4038 22.862 SiO2 |
4 -805.2878 0.562 |
5 200.3927 22.916 SiO2 |
6 -5488.5929 2.017 |
7 175.9518 13.200 SiO2 |
8 89.3671 23.506 |
9 -251.2940 13.200 SiO2 |
10 117.6377 17.782 |
11 -385.3813 13.200 SiO2 |
12 202.4207 45.924 |
13 -91.0702 37.285 SiO2 |
14 -127.3432 1.121 |
15 -328.0513 21.515 SiO2 |
16 -189.7883 0.500 |
17 586.2480 32.616 SiO2 |
18 -361.8688 0.500 |
19 245.8447 42.666 SiO2 |
20 -473.1517 0.500 |
21 264.6374 23.142 SiO2 |
22 1048.3873 0.500 |
23 148.4737 29.015 SiO2 |
24 103.0984 32.942 |
25 -206.3282 13.200 SiO2 |
26 123.7969 32.915 |
27 -131.6399 21.033 SiO2 |
28 7701.8857 36.508 |
AS Infinity 16.112 |
29 -464.5546 22.943 SiO2 |
30 -196.3589 0.500 |
31 550.6776 31.300 SiO2 |
32 -389.3637 0.500 |
33 267.4490 35.966 SiO2 |
34 -973.8704 16.994 |
35 -249.5509 13.200 SiO2 |
36 -422.7325 0.651 |
37 292.4468 39.221 SiO2 |
38 -482.4755 0.500 |
39 142.3114 33.754 SiO2 |
40 562.9071 0.500 |
41 127.0463 21.871 SiO2 |
42 203.4267 12.627 |
43 -1103.3518 49.378 SiO2 |
44 49.2801 10.479 |
45 47.7728 20.357 SiO2 |
46 657.3074 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses. |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, δ34 is the axial distance from the last optical surface of the third group of lenses to the first optical surface of the fourth group of lenses, h4a is the maximum height of a paraxial marginal ray on each optical surface of the second negative refractive power lens in the fourth group of lenses, h4max is the maximum height of a paraxial marginal ray in the fourth group of lenses, f4a is the focal length of the second negative refractive power lens of the fourth group of lenses, q4a is the shape factor of the second negative refractive power lens, g is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
FIG. 5A shows a fifth embodiment of the present invention. The fifth embodiment includes four negative refractive power lenses in rear lens group G1r in the first group of lenses G1. The four negative refractive power lenses allow the required negative refractive power to be divided between four lenses. FIGS. 5B to 5E show measured optical aberrations of the lens arrangement as shown in FIG. 5A. Example 5 is a listing of numerical values for Embodiment 5 shown in FIG. 5A.
______________________________________ |
Object plane to first optical surface = 109.084 mm |
Last optical surface to image plane = 15.508 mm |
En = 3714.136 mm |
Ex = -6439.431 mm |
f1 = -1409.164 mm |
f2 = 128.024 mm |
f3 = -81.115 mm |
f4 = 115.796 mm |
β1 = 0.4608 |
β4 = -0.6267 |
q32 = -0.2500 |
f4b = -93.685 mm |
δ34 = 50.705 mm |
h4a = 82.568 mm |
h4max = 88.303 mm |
f4a = -1123.899 mm |
q4a = 3.844 |
β = -0.25 |
L = 980.000 mm |
Radius of axial lens |
Surface # |
Curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 1429.4466 23.206 SiO2 |
2 -237.8825 2.679 |
3 284.9490 18.564 SiO2 |
4 2543.1908 0.901 |
5 182.9345 22.354 SiO2 |
6 1843.7771 0.500 |
7 156.9109 13.200 SiO2 |
8 92.2005 10.950 |
9 195.3680 13.200 SiO2 |
10 99.6277 20.263 |
11 -205.8066 13.200 SiO2 |
12 170.3134 22.789 |
13 -2041.9105 13.200 SiO2 |
14 250.8359 39.135 |
15 -101.0171 38.918 SiO2 |
16 -138.9455 0.500 |
17 -371.9355 21.216 SiO2 |
18 -208.5422 0.500 |
19 456.0090 37.838 SiO2 |
20 -334.2789 0.500 |
21 260.2819 40.620 SiO2 |
22 -571.1082 0.500 |
23 253.6973 22.836 SiO2 |
24 738.8543 0.500 |
25 151.1963 30.931 SiO2 |
26 103.4086 33.478 |
27 -216.0894 13.200 SiO2 |
28 129.6536 29.657 |
29 -140.3622 15.849 SiO2 |
30 1464.5072 31.048 |
AS Infinity 19.657 |
31 -717.8963 25.457 SiO2 |
32 -195.6305 0.500 |
33 481.0396 28.100 SiO2 |
34 -570.0658 0.500 |
35 277.7841 35.703 SiO2 |
36 -762.9426 17.046 |
37 -229.4275 13.200 SiO2 |
38 -390.7874 0.500 |
39 300.1620 38.930 SiO2 |
40 -450.2510 0.500 |
41 129.3465 37.088 SiO2 |
42 623.5795 0.500 |
43 115.7912 20.137 SiO2 |
44 153.2106 14.003 |
45 -1346.7279 35.923 SiO2 |
46 49.8199 11.440 |
47 49.6263 23.992 SiO2 |
48 591.8956 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses. |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, δ34 is the axial distance from the last optical surface of the third group of lenses to the first optical surface of the fourth group of lenses, h4a is the maximum height of a paraxial marginal ray on each optical surface of the second negative refractive power lens in the fourth group of lenses, h4max is the maximum height of a paraxial marginal ray in the fourth group of lenses, f4a is the focal length of the second negative refractive power lens of the fourth group of lenses, q4a is the shape factor of the second negative refractive power lens, g is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
FIG. 6A shows a sixth embodiment of the present invention. In the sixth embodiment, the second group of lenses G2 includes five positive refractive power lenses. FIGS. 6B to 6E show measured optical aberrations of the lens arrangement as shown in FIG. 6A. Example 6 is a listing of numerical values for Embodiment 6 shown in FIG. 6A.
______________________________________ |
Object plane to first optical surface = 116.330 mm |
Last optical surface to image plane = 15.465 mm |
En = 3879.674 mm |
Ex = -6705.945 mm |
f1 = -1780.333 mm |
f2 = 125.073 mm |
f3 = -80.363 mm |
f4 = 114.542 mm |
β1 = 0.4672 |
β4 = -0.6267 |
q32 = -0.2504 |
f4b = -95.400 mm |
δ34 = 54.136 mm |
h4a = 81.238 mm |
h4max = 87.926 mm |
f4a = -1114.151 mm |
q4a = 3.556 |
β = -0.25 |
L = 980.000 |
Radius of axial lens |
Surface # |
Curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 -9940.0000 21.075 SiO2 |
2 -248.4887 8.198 |
3 336.5503 20.761 SiO2 |
4 -1124.2938 0.788 |
5 183.7585 21.971 SiO2 |
6 1033.1260 0.500 |
7 134.2105 13.200 SiO2 |
8 87.4010 9.239 |
9 137.9589 13.200 SiO2 |
10 89.7449 16.813 |
11 -4452.5483 13.200 SiO2 |
12 121.2519 19.897 |
13 -147.6844 13.200 SiO2 |
14 1164.5237 27.243 |
15 -128.3377 13.200 SiO2 |
16 -1059.8158 11.076 |
17 -240.4526 20.904 SiO2 |
18 -151.4361 0.736 |
19 -990.5425 24.776 SiO2 |
20 -234.0813 0.500 |
21 412.6743 39.639 SiO2 |
22 -303.6065 0.500 |
23 259.0267 37.787 SiO2 |
24 -670.6207 0.500 |
25 237.3712 22.511 SiO2 |
26 627.5033 0.500 |
27 154.9542 30.365 SiO2 |
28 106.3850 31.852 |
29 -213.5493 13.200 SiO2 |
30 128.0273 27.700 |
31 -147.8348 15.548 SiO2 |
32 797.8470 33.038 |
AS Infinity 21.098 |
33 -810.3877 25.016 SiO2 |
34 -203.8756 0.500 |
35 446.1791 30.359 SiO2 |
36 -489.3865 0.500 |
37 256.9021 35.758 SiO2 |
38 -987.1242 16.957 |
39 -242.8093 13.200 SiO2 |
40 -432.7711 0.500 |
41 297.6719 38.256 SiO2 |
42 -445.5888 0.500 |
43 130.6978 33.678 SiO2 |
44 467.2291 0.500 |
45 125.4406 20.743 SiO2 |
46 181.5910 12.694 |
47 -1066.6382 37.762 SiO2 |
48 51.4183 9.830 |
49 50.2058 26.738 SiO2 |
50 643.2380 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses. |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, δ34 is the axial distance from the last optical surface of the third group of lenses to the first optical surface of the fourth group of lenses, h4a is the maximum height of a paraxial marginal ray on each optical surface of the second negative refractive power lens in the fourth group of lenses, h4max is the maximum height of a paraxial marginal ray in the fourth group of lenses, f4a is the focal length of the second negative refractive power lens of the fourth group of lenses, q4a is the shape factor of the second negative refractive power lens, β is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
FIG. 7A shows a seventh embodiment of the present invention. In the seventh embodiment, the front group of lenses G1f in the first group of lenses includes a negative refractive power lens 28 and the fourth group of lenses G4 includes an additional negative refractive power lens 30. FIGS. 7B to 7E show measured optical aberrations of the lens arrangement as shown in FIG. 7A. Example 7 is a listing of numerical values for Embodiment 7 shown in FIG. 7A.
______________________________________ |
Object plane to first optical surface = 101.315 mm |
Last optical surface to image plane = 17.121 mm |
En = 4696.014 mm |
Ex = -8565.667 mm |
f1 = -1348.993 mm |
f2 = 119.766 |
f3 = -78.844 mm |
f4 = 111.828 mm |
β1 = 0.4390 |
β4 = -0.6267 |
q32 = -0.2500 |
h4a = 82.681 mm |
h4max = 86.591 mm |
f4a = -1203.687 mm |
q4a = 4.267 β = -0.25 |
L = 980.000 mm |
Radius of axial lens |
Surface # |
Curvature (mm) |
distance (mm)* |
material |
______________________________________ |
1 406.8004 13.200 SiO2 |
2 261.7001 7.790 |
3 419.3418 22.077 SiO2 |
4 -487.5762 0.888 |
5 302.6092 22.271 SiO2 |
6 -970.5439 0.500 |
7 188.3639 24.131 SiO2 |
8 Infinity 0.500 |
9 156.4066 13.200 SiO2 |
10 91.4023 11.070 |
11 176.1740 13.242 SiO2 |
12 98.5191 18.147 |
13 486.4538 13.200 SiO2 |
14 128.3436 19.474 |
15 -148.9359 13.200 SiO2 |
16 282.0349 21.168 |
17 -113.3427 13.205 SiO2 |
18 -591.5183 9.481 |
19 -241.0986 20.757 SiO2 |
20 -149.1301 1.343 |
21 -767.1261 25.531 SiO2 |
22 -208.1746 0.500 |
23 496.1750 40.582 SiO2 |
24 -251.6479 0.500 |
25 250.5406 36.133 SiO2 |
26 -915.0211 0.509 |
27 215.2170 23.766 SiO2 |
28 566.5459 0.947 |
29 163.9259 32.534 SiO2 |
30 104.2115 32.160 |
31 -237.2329 14.394 SiO2 |
32 142.3397 30.267 |
33 -135.2560 14.803 SiO2 |
34 772.2937 29.959 |
AS Infinity 21.994 |
35 -1226.2055 25.988 SiO2 |
36 -204.8952 0.500 |
37 734.4489 26.659 SiO2 |
38 -430.4449 0.500 |
39 314.3788 33.736 SiO2 |
40 -613.8078 15.134 |
41 -224.8719 13.200 SiO2 |
42 -362.5427 1.771 |
43 321.3405 36.356 SiO2 |
44 -462.8995 0.500 |
45 121.8532 37.127 SiO2 |
46 444.1222 0.500 |
47 107.2585 22.132 SiO2 |
48 149.3250 12.346 |
49 1314.4992 13.555 SiO2 |
50 60.2330 10.045 |
51 92.2038 25.386 SiO2 |
52 66.7739 1.132 |
53 52.6255 21.574 SiO2 |
54 1108.8530 |
______________________________________ |
*The axial distance is either axial lens thickness or axial distance |
between adjacent lenses. |
En is the distance measured from the first optical surface on the object side of the optical system to the entrance pupil of the optical system, Ex is the distance measured from the last optical surface on the image side of the optical system to the exit pupil of the optical system, f1 is the focal length of the first group of lenses G1, f2 is the focal length of the second group of lenses G2, f3 is the focal length of the third group of lenses G3, f4 is the focal length of the fourth group of lenses G4, β1 is the magnification of the first group of lenses, β4 is the magnification of the fourth group of lenses, q32 is the shape factor of the negative refractive power lens in the third group of lenses, f4b is the focal length of the negative refractive power lens in the fourth group of lenses, h4a is the maximum height of a paraxial marginal ray on each optical surface of the second negative refractive power lens in the fourth group of lenses, h4max is the maximum height of a paraxial marginal ray in the fourth group of lenses, f4a is the focal length of the second negative refractive power lens of the fourth group of lenses, q4a is the shape factor of the second negative refractive power lens, β is the overall magnification of the optical system, and L is the distance between object and image of the optical system.
FIG. 8 shows a schematic setup of a scanning exposure apparatus in which the projection optical system according to the present invention could be applied. In the exposure apparatus shown in FIG. 8, the reticle 34, which in this case is a photomask in which predetermined circuit patterns are formed, is disposed on the object plane 12 of the projection optical system 36 and the wafer 38 which is a photosensitive substrate is disposed on the image plane 14 of the projection optical system 36. The reticle 34 is held on a reticle stage 42 arranged to move in the X-direction upon exposure, and the wafer 38 is held on a wafer stage 44 arranged to move in the -X direction opposite to movement of the reticle stage 42. A rectangular slit 46 forms an illumination area 47 extending in the Y-direction on reticle 34, and an illumination optical system 48 is disposed above reticle 34. The illumination optical system 48 includes a light source 50. In this arrangement, the light supplied from the light source 50 in the illumination optical system 48 illuminates reticle 34 in a slit pattern. An image of the light source 50 in the illumination optical system 48 is formed at the position of the pupil (the position of aperture stop 16) of the projection optical system 36. This arrangement provides Kohler illumination. The image of the pattern of reticle 34 while being Kohler-illuminated is projected (or transferred) onto wafer 38 through projection optical system 36. The photosensitive substrate placed on wafer stage 44 is one obtained by coating the entire surface of exposed object 52 such as a silicon wafer, a glass plate, or the like with a photosensitive material 54 such as a photoresist, as shown in FIG. 9. The pattern image of reticle 34 formed on wafer 38 is a slit pattern (rectangular shape extending in the Y-direction, as indicated at 56, FIG. 8. Thus, when the projection magnification factor of the projection optical system 36 is 1/M=β, the reticle stage 42 and wafer stage 44 are moved in mutually opposite directions along the X-direction in the velocity ratio of M:1, whereby the pattern image of the entire surface of reticle 34 is transferred onto the wafer 38.
The above embodiments show examples of the projection optical system to which an excimer laser for supplying light having the exposure wavelength λ of 248 nm is applicable as a light source 50 disposed inside the illumination optical system 48. FIGS. 1A to 7E show lens layouts of the first to seventh embodiments of the projection optical system according to the present invention.
Each embodiment above showed an example using the KrF excimer laser with a wavelength of λ equal to 248 nm as a light source. Further, light sources applicable to each embodiment include extreme ultraviolet light sources such as the ArF excimer laser supplying light at a wavelength of 193 nm, a mercury arc lamp supplying the light of the g-line (436 nm) and the i-line (365 nm), and light sources supplying light in the ultraviolet region other than the above.
In each embodiment, the lenses constituting the projection optical system are not cemented and all are made of a single optical material, silica (SiO2). Because each embodiment as described above is constructed of a single optical material, cost reduction is achieved. However, if the exposure light has some half-width, it is preferred to construct the projection optical system with a combination of lenses of silica (SiO2) and lenses of fluorite (CaF2) or a combination of lenses made of various types of different materials in order to correct chromatic aberration. Particularly, if the exposure light source has a wide band, it is effective to correct for chromatic aberration by constructing the projection optical system by preparing plural types of lenses and combining those lenses.
Further, the examples of the projection optical system of the first to seventh embodiments were described as applications to the scanning exposure apparatus, as shown in FIG. 8. However, the exposure apparatus to which the projection optical system of the present invention can be applied includes exposure apparatus of the one-shot exposure method for printing the patterns of reticle 34 on wafer 38 with one shot, for example, as shown in FIG. 10. It is noted that like numerals are used for like components in FIG. 10 as those shown in FIG. 8. The difference between FIG. 8 and FIG. 10 is that the shape of the image 46 in FIG. 10 is comprehends the entire surface of the reticle 34 and the shape of the image 47 in FIG. 8 is a rectangular slit which must be scanned over the surface of reticle 34.
As described above, the projection optical system according to the present invention is a bitelecentric optical system and realizes the high-resolution-power optical system as corrected for various aberrations in a good balance and having the large numerical aperture while securing a relatively wide exposure area.
The foregoing description of the embodiments of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiments were chosen and described to provide the best illustration of the principles of the invention and its practical application to thereby enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the invention as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.
For example, in the above examples, a single glass material, fused silica (SiO2), was used as an optical material for the projection optical system, but if narrowing of the bandwidth of the exposure light spectrum is not adequate, it is possible to compensate chromatic aberration by using fused silica (SiO2) and fluorite (CaF2). In addition, other variations can be made, for example, chromatic aberration can be compensated by using other optical materials with a superior transmittance factor in the ultraviolet range. This would allow the projection optical system, as described above, to be applicable to cases where other light sources are used. It is not intended that the present invention be restricted to a projection optical system using excimer lasers.
Patent | Priority | Assignee | Title |
5956182, | Aug 07 1996 | Nikon Corporation | Projection optical system |
5990926, | Jul 16 1997 | Nikon Corporation | Projection lens systems for excimer laser exposure lithography |
6008884, | Apr 25 1997 | Nikon Corporation | Projection lens system and apparatus |
6198576, | Jul 16 1998 | Nikon Corporation | Projection optical system and exposure apparatus |
6259508, | Jan 22 1998 | Nikon Corporation | Projection optical system and exposure apparatus and method |
6333781, | Jul 24 1997 | Nikon Corporation | Projection optical system and exposure apparatus and method |
6538821, | Sep 22 1997 | Nikon Corporation | Projection optical system |
6556353, | Feb 23 2001 | Nikon Corporation | Projection optical system, projection exposure apparatus, and projection exposure method |
6563577, | Apr 21 2000 | Nikon Corporation | Defect testing apparatus and defect testing method |
6606144, | Sep 29 1999 | Nikon Corporation | Projection exposure methods and apparatus, and projection optical systems |
6674513, | Sep 29 1999 | Nikon Corporation | Projection exposure methods and apparatus, and projection optical systems |
6700645, | Jan 22 1998 | Nikon Corporation | Projection optical system and exposure apparatus and method |
6781766, | Sep 22 1997 | Nikon Corporation | Projection optical system |
6862078, | Feb 21 2001 | Nikon Corporation | Projection optical system and exposure apparatus with the same |
6864961, | Sep 29 1999 | Nikon Corporation | Projection exposure methods and apparatus, and projection optical systems |
7088427, | Apr 20 2004 | Litel Instruments | Apparatus and method for high resolution in-situ illumination source measurement in projection imaging systems |
7450312, | Oct 21 1999 | Carl Zeiss SMT AG | Optical projection lens system |
7684134, | Jan 21 2003 | The General Hospital Corporation | Microscope objectives |
7869122, | Jan 14 2004 | Carl Zeiss SMT AG | Catadioptric projection objective |
7957069, | Dec 30 2004 | Carl Zeiss SMT AG | Projection optical system |
8199400, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective |
8208198, | Jan 14 2004 | Carl Zeiss SMT AG | Catadioptric projection objective |
8208199, | Jan 14 2004 | Carl Zeiss SMT AG | Catadioptric projection objective |
8289619, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective |
8339701, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective |
8355201, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective |
8416490, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective |
8730572, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective |
8804234, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective including an aspherized plate |
8908269, | Jan 14 2004 | Carl Zeiss SMT GmbH | Immersion catadioptric projection objective having two intermediate images |
8913316, | May 17 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective with intermediate images |
9019596, | May 17 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective with intermediate images |
9134618, | May 17 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective with intermediate images |
9726979, | May 17 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective with intermediate images |
9772478, | Jan 14 2004 | Carl Zeiss SMT GmbH | Catadioptric projection objective with parallel, offset optical axes |
Patent | Priority | Assignee | Title |
3909115, | |||
4089591, | Mar 22 1975 | Carl Zeiss Stiftung | Extremely high speed objective |
4666273, | Oct 05 1983 | Nippon Kogaku K. K. | Automatic magnification correcting system in a projection optical apparatus |
4770477, | Dec 04 1986 | SVG LITHOGRAPHY, INC , A CORP OF DE | Lens usable in the ultraviolet |
4772107, | Nov 05 1986 | SVG LITHOGRAPHY, INC , A CORP OF DE | Wide angle lens with improved flat field characteristics |
4811055, | Feb 27 1984 | CANON KABUSHIKI KAISHA, A CORP OF JAPAN | Projection exposure apparatus |
4891663, | Dec 28 1983 | Canon Kabushiki Kaisha | Projection exposure apparatus |
4977426, | Dec 28 1983 | Canon Kabushiki Kaisha | Projection exposure apparatus |
5105075, | Sep 19 1988 | Canon Kabushiki Kaisha | Projection exposure apparatus |
5170207, | Dec 12 1990 | Olympus Optical Co., Ltd. | Projection lens system |
5221995, | Aug 12 1989 | Asahi Kogaku Kogyo K.K. | Zoom lens system |
5260832, | Oct 22 1990 | Nikon Corporation | Projection lens system |
5526186, | Mar 29 1994 | Nikon Corporation | Zoom lens system |
EP712019A2, | |||
JP5173065, | |||
JP7140384, | |||
JP7140385, |
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